Superconducting cable

ABSTRACT

Provided is a superconducting cable capable of maintaining a predetermined thermal insulation property without having a vacuum thermal insulation structure. The superconducting cable of the present invention comprises: a cable unit  100 , in which a core having a superconductor layer and an electrical insulation layer is housed in a core-housing pipe; a thermal insulation member  200  which is provided outside the cable unit and maintained in a non-vacuum state; and a sealing member for preventing the permeation of moisture into the thermal insulation member. By equipping the outside of the cable unit with the thermal insulation member  200  which is maintained in a non-vacuum state, it is made possible to maintain the predetermined thermal insulation property without having a vacuum thermal insulation structure.

TECHNICAL FIELD

The present invention relates to a superconducting cable.

Particularly, the invention relates to a superconducting cable that doesnot have a vacuum thermal insulation structure, or a superconductingcable that has a vacuum thermal insulation structure and that canmaintain the thermal insulation performance even if the vacuum conditionis destroyed.

BACKGROUND ART

The superconducting cable as shown in FIG. 8 is a proposed conventionalsuperconducting cable. FIG. 8 is a sectional view of a three core-in-onetype superconducting cable having a structure in which three cores 110are housed in a thermal insulation pipe 600.

A cable core 110 is equipped with a former 111, a superconductor layer112, an electrical insulation layer 113, a shielding layer 114, and aprotective layer 115, in an enumerated order from the center thereof.The conductor layer 112 is formed by spirally winding superconductingwires in multiple layers on the former 111. Generally, a superconductingwire has a structure of tape-like shape in which a plurality offilaments consisting of an oxide superconducting material are arrangedin a matrix such as a silver sheath. The insulation layer 113 is formedby winding an insulation paper such as a semisynthetic insulation paper.The shielding layer 114 is formed by spirally winding a superconductingwire, which is similar to the conductor layer 112, on the electricalinsulation layer 113. An insulation paper or the like is used as theprotective layer 115.

On the other hand, a thermal insulation pipe 600 is structured such thata thermal insulation material (not illustrated) is arranged between thedouble pipes consisting of an inner pipe 610 and an outer pipe 620, theinside of the double pipe is evacuated. An anticorrosion layer 630 isformed outside the thermal insulation pipe 600. Furthermore, the spaceexisting inside the former 111 (in the case where the former is hollow)and a space between the inner pipe 610 and the cores 110 are filled witha coolant such as liquid-nitrogen or the like which circulates thereinso that the thermal insulation pipe may be in a usable condition in astate of the insulation layer 113 being impregnated with the coolant.

-   -   [Patent document 1] Japanese Patent Application Publication No.        2002-140944 (FIG. 2)

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention

However, there have been the following problems with respect to theabove-mentioned superconducting cable.

(1) The vacuum thermal insulation structure needed for thesuperconducting cable results in a large-sized cable. In order to make avacuum thermal insulation structure, it is necessary to use a thermalinsulation pipe having a double pipe structure and to evacuate the spacebetween the inner and the outer pipes of the thermal insulation pipe.Therefore, the thickness of the thermal insulation pipe increases, andparticularly the outer diameter of the superconducting cable becomeslarge-sized. Accordingly, the manufacturing cost of the superconductingcable becomes high.

(2) The maintenance and control of the vacuum performance of the thermalinsulation pipe are complex. Using an evacuated thermal insulation pipehaving a double pipe structure requires the maintenance and control ofthe vacuum performance in the manufacture, construction and operationsteps of the superconducting cable. Particularly, when a malfunctionoccurs to the vacuum performance of the thermal insulation pipe, ittakes a large amount of time to recover the pre-determined vacuumcondition once again. Depending on the conditions, it may be difficultto recover the pre-determined vacuum condition within a given period oftime, which might result in failure of maintaining the coolanttemperature, thereby causing a lack of a power transmission property.

The present invention was accomplished in view of the above-mentionedsituation, and the main object of the invention is to provide asuperconducting cable which is capable of maintaining a predeterminedthermal insulation property without having a vacuum thermal insulationstructure.

Another object of the present invention is to provide a superconductingcable having a vacuum thermal insulation structure and capable ofmaintaining a predetermined thermal insulation property even if thevacuum condition is destroyed.

Means for Solving the Problems to be Solved

The present invention achieves the above-mentioned objects by using athermal insulation member other than the vacuum thermal insulation.

A superconducting cable of the present invention is characterized inthat the cable comprises a cable unit, a thermal insulation member, anda sealing member: the cable unit is composed of a core, which has asuperconductor layer and an electrical insulation layer, and acore-housing pipe for housing the core; the thermal insulation member isprovided outside the cable unit and maintained in a non-vacuum state;and the sealing member prevents the permeation of moisture into thethermal insulation member.

By arranging the thermal insulation member of non-vacuum conditionoutside the cable unit, a predetermined thermal insulation property canbe maintained without adopting a vacuum thermal insulation structure. Byproviding the thermal insulation member with a sealing member, it ismade possible to prevent moisture from permeating into the thermalinsulation member and to maintain the thermal insulation propertythereof.

Hereinafter, the superconducting cable of the present invention will bedescribed in more detail.

The superconducting cable of the present invention has a cable unit, athermal insulation member maintained in a non-vacuum condition, and asealing member for preventing the permeation of moisture into thethermal insulation member.

<Cable Unit>

The cable unit consists of a core and a core-housing pipe which housesthe core. The core has at least a superconductor layer and an electricalinsulation layer. Typically, the core is equipped with a former, asuperconductor layer, an electrical insulation layer, a shielding layer,and a protective layer in the enumerated order from the center. Theshielding layer may also be comprised of a superconducting wire.

The former which is used for maintaining the given shape of asuperconductor layer may be of pipe-like shape, or may be made ofstranded wires. The suitable material for the former is, for example, anon-magnetic metallic material such as copper or aluminum. In the caseof a former having a pipe-like shape, it is possible to use the insideof the former as a channel of a coolant.

The superconductor layer is formed by, for example, spirally winding thewires made of a superconducting material around the former. Asuperconducting wire is, for example, structured in a tape-like shapesuch that a plurality of filaments consisting of Bi-2223 oxidesuperconducting material are arranged in a matrix of silver sheath. Thewinding of the superconducting wire may be made either in a single layeror in multiple layers. In the case of multiple layers, an inter-levelisolation layer may be provided. The inter-level isolation layer may beprovided, for example, by winding an insulation paper such as kraftpaper, or winding a semisynthetic insulating paper such as PPLP(registered trademark, made by Sumitomo Electric Industries, Ltd.).

The electrical insulation layer is formed preferably by winding aninsulation paper such as a semi-synthetic paper, e.g., PPLP (registeredtrademark, from Sumitomo Electric Industries, Ltd.) which is made bylaminating polypropylene and kraft paper, or winding an insulation papersuch as kraft paper. Also, a semiconductive layer may be formed at leastat one side of the electrical insulation layer, that is, between theconductor layer and the electrical insulation layer, or between theelectrical insulation layer and the shielding layer. By forming an innersemiconductive layer (i.e., the former case), or an outer semiconductivelayer (i.e., the latter case), the adhesion between the conductor layerand the electrical insulation layer or between the electrical insulationlayer and the shielding layer is enhanced, and the deterioration due tothe occurrence of partial electrical discharge or the like isrestrained.

Also, it is preferable to provide a shielding layer outside theelectrical insulation layer. The shielding layer may be formed by anelectrical conducting material, and it is preferable that the same kindof superconducting wire as that of the conductor layer be wound aroundthe electrical insulation layer in order to form the shielding layer.Using a superconducting wire for a shielding layer makes it possible torestrain an electric current having an opposite phase relative to theconductor electric current from flowing into the shielding layer and torestrain a magnetic field of alternating current from leaking outside.

Besides, a cushion layer may be interposed between the former and theconductor layer. The cushion layer avoids direct contact of metalsbetween the former and the superconducting wire, and consequentlyprevents the superconducting wire from being damaged. Particularly, whenthe former is formed in a stranded-wire structure, the cushion layer canfunction as a means for smoothing the surface of the former. Preferably,the cushion layer may be made of insulation paper or carbon paper.

On the other hand, the core-housing pipe, which is a tubular materialfor housing a core, has a function of mechanically protecting the core.For example, a corrugated pipe made of stainless steel or aluminum canbe used as the core-housing pipe. Basically, this core-housing pipe isnot required to exhibit thermal insulation performance for maintainingthe coolant temperature of the cable unit, and the thermal insulationfunction is borne by a thermal insulation member described later. Inother words, preferably, the core-housing pipe is not equipped with athermal insulation layer. With such structure, the outer diameter of thecore-housing pipe can be decreased to the practically possible minimum.

However, the core-housing pipe may have a thermal insulation function.In such case, it does not matter whether the thermal insulationstructure is vacuum thermal insulation or non-vacuum thermal insulation.When a vacuum thermal insulation structure is adopted for thecore-housing pipe, the outer diameter of the cable unit cannot be madesmaller as compared with a conventional superconducting cable, but it isnot a problem because, if the vacuum performance deteriorates, thethermal insulation property of the cable unit is maintainedindependently by the thermal insulation member described later or bycombination of the thermal insulation property of the core-housing pipeand the thermal insulation property of the thermal insulation member. Inorder to decrease the outer diameter of the cable part while a vacuumthermal insulation structure is adopted in the core-housing pipe, it isconceivable to make the vacuum degree of the core-housing pipe lowerthan the vacuum degree of the thermal insulation pipe in a conventionalsuperconducting cable. Also, when a non-vacuum thermal insulationstructure is adopted for the core-housing pipe, the thermal insulationproperty is designed to be lower than the thermal insulation propertythat is needed for maintaining the coolant temperature of the cableunit. In such case, the non-vacuum thermal insulation structure of thecore-housing pipe can be simplified, and the necessary thermalinsulation property for maintaining the coolant temperature of the cableunit can be secured by the combination of the non-vacuum thermalinsulation structure of the core-housing pipe and the thermal insulationmember mentioned hereinlater.

<Thermal Insulation Member>

A thermal insulation member which is maintained in a non-vacuumcondition is arranged outside such core-housing pipe. The thermalinsulation member is basically required to have thermal insulationperformance of maintaining the coolant temperature of the cable unit.The structure of the thermal insulation member is preferably at leasteither one of a multi-layer thermal insulation and a filling thermalinsulation. As for the multi-layer thermal insulation, the so-calledsuper insulation (which is made by laminating a metal foil and plasticmeshes) which is also used in a conventional superconducting cables canpreferably be used. On the other hand, the filling thermal insulationmay preferably use glass wool, expandable plastics, sand, gravel, etc.

Particularly, aerojel is a desirable material for the thermal insulationmember. The aerojel, which is a porous material including a number ofvery minute nano-size vacancies, has high adiabaticity. For example,silica aerojel has many vacancies of 10 nm in average and very highadiabaticity with the coefficient of thermal conductivity being 10mW/m-K (38° C., 1 atm), and moreover, it is remarkably light-weight. Anexample of aerojel that can be used is Pyrogel (trade name) from AspenAerogels, Inc.

By using either of a multi-layer thermal insulation and a fillingthermal insulation independently, or by using both of them incombination, for a thermal insulation member, it is possible to obtainsuperconducting cables which comply with various requiredcharacteristics. Generally, the multi-layer thermal insulation can covera cable unit in such a manner as winding, and hence it is easy to makethe outer shape of the multi-layer thermal insulation in a circularcylindrical form. On the other hand, the filling thermal insulation,which has high degree of freedom in terms of material characteristicsand outer shape, can allow choosing various materials and outer shapes,thereby enabling selection according to installation conditions,allowable size, and allowable cost. For example, it is desirable thatthe multi-layer thermal insulation be disposed on the innercircumferential part of the thermal insulation member, with the fillingthermal insulation being disposed on the outer circumferential part ofthe thermal insulation member. By arranging the multi-layer thermalinsulation on the inner circumference side, mainly radiant heat caneffectively be insulated, and thereby high thermal insulation propertycan be obtained. By arranging the filling thermal insulation on theouter peripheral side, it is made possible to select a suitable outershape of the superconducting cable according to the installationconditions.

<Sealing Member>

The above-mentioned thermal insulation member is arranged outside thecable unit and is sealed up with a sealing member. The sealing memberhas the function of preventing the permeation of moisture into thethermal insulation member and thereby maintaining the thermal insulationproperty of the thermal insulation member. Also, the thermal insulationmember, which is a multi-layer thermal insulation or a filling thermalinsulation as mentioned above, has a difficulty in maintaining a givenshape by itself, and hence the sealing member has a function ofmaintaining the thermal insulation member in a predetermined shape so asnot to come apart.

The sealing member is comprised of a material which can prevent thepermeation of moisture. For example, a metallic pipe, metallic sheet, ora laminated material made of metallic sheet and plastic sheet, etc. canpreferably be used. These metallic sheets and laminated materials coverthe outer periphery of the thermal insulation member, and prevent thepermeation of moisture by jointing the mutual edges of the sheets bymeans of welding or adhesion. Aluminum, aluminum alloy, stainless steel,etc. can preferably be used for the metallic pipe and the metallicsheet.

<Arrangement of a Plurality of Cable Units>

The above-mentioned superconducting cable may have either a single cableunit or a plurality of cable units. In the case of a plurality of cableunits, preferably the cable units are arranged at positions close toeach other. Particularly, it is preferable to arrange a plurality ofcable units at positions close to each other within a common thermalinsulation member. The contact area (per single cable unit) between thecable unit group and the thermal insulation member is smaller in thecase where a plurality of cable units are closely placed altogether inthe thermal insulation member as compared with the case where aplurality of cable units are each placed independently in the respectivethermal insulation member. Therefore, the amount of penetrating heat percable unit can be decreased. Particularly, it is possible for each cableunit to cool the other adjacent cable unit mutually, and accordinglymore effect of the thermal insulation can be expected.

Ideally, the intervals between the respective cable units are zero, thatis, the cable units are in contact with each other. In the case of aninterval existing between the cable units, preferably it should be equalto or less than the outer diameter of the cable unit. Choosing such aninterval results in reduction of heat penetration per cable unit. Morepreferably, the interval between the cable units is equal to or lessthan half the outer diameter of the cable unit.

<Composition of Coolant Transport Tube>

Besides, a coolant transport tube may be provided near a cable unit. Thecoolant transport tube as mentioned herein is a duct used fortransporting various kinds of coolants. Typically, the duct is atransport tube used for liquid-hydrogen, liquid oxygen, liquid-nitrogenor liquid natural gas, etc. These coolant transport tubes, which aregenerally used for transporting a coolant having a cryogenic temperatureused at a hydrogen station or various kinds of plants, are capable ofperforming thermal insulation (cooling) of the cable unit moreefficiently if they are arranged near the cable unit in the thermalinsulation member.

The coolant transport tube is placed preferably near the cable unit asin the case where a plurality of cable units are arranged. In this caseit is also desirable to make an interval the same as a mutual intervalof the cable units. In other words, the coolant temperature of thecoolant transport tube can be expected to cool the cable unit near thecoolant transport tube in particular when the coolant temperature of thecoolant transport tube is lower than the coolant temperature for coolingthe superconductor layer of the cable unit.

However, depending on the relationship between the coolant temperaturewhich cools the superconductor layer of the cable unit and the coolanttemperature of the coolant transport tube, an auxiliary thermalinsulation structure may be provided at least at either one of the cableunit and the coolant transport tube. The auxiliary thermal insulationstructure is a thermal insulation structure for preventing therespective coolant of the cable unit and the coolant transport tube fromfalling out of the range of proper temperature mainly by the mutual heatmovement between the cable unit and the coolant transport tube.

For example, in the case where the coolant of the cable unit isliquid-nitrogen (boiling point: about 77 K, melting point: about 63 K),and the coolant of the coolant transport tube is liquid-hydrogen(boiling point: about 20 K), the liquid-nitrogen of the cable unit mightbe so excessively cooled as to be solidified, or the liquid-hydrogen ofthe coolant transport tube might be so warmed as to vaporize, if thecable unit and the coolant transport tube are disposed mutually tooclose. Therefore, it is preferable to provide the cable unit with anauxiliary thermal insulation structure, for example, in order torestrain the liquid-nitrogen of the cable unit from being excessivelycooled more than necessary, or to restrain the liquid-hydrogen of thecoolant transport tube from being warmed up. Particularly, it ispreferable that the thermal insulation structure be designed such thatthe thermal amount with which a cable unit is warmed up by thepenetrating heat from the outside is balanced with the thermal amountwith which the cable unit is cooled by cold from the coolant transporttube, so that both the cable unit and the coolant transport tube caneasily maintain the proper temperature.

Besides, in the case where the coolant of the cable unit isliquid-nitrogen (boiling point: about 77 K, melting point: about 63 K)and the coolant of the coolant transport tube is liquid natural gas, LNG(boiling point: about 110 K, melting point: about 90 K), depending onthe structure of, and the distance between the cable unit and thecoolant transport tube, the liquid-nitrogen of the cable unit might beso warmed as to vaporize or the liquid natural gas might be soexcessively cooled as to be solidified. Therefore, it is preferable thatthe coolant transport tube be equipped with an auxiliary thermalinsulation structure so that the liquid-nitrogen of the cable unit maybe restrained from warming up or a liquid natural gas may be preventedfrom being excessively cooled more than necessary. Particularly, it ispreferable that the thermal insulation structure be designed such thatthe thermal amount with which the coolant transport tube is warmed up bythe penetrating heat from the outside is balanced with the thermalamount with which the coolant transport tube is cooled by cold from thecable unit, so that both the cable unit and the coolant transport tubecan easily maintain the proper temperature.

The auxiliary thermal insulation structure to be provided for the cableunit or the coolant transport tube may also be either a vacuum thermalinsulation structure or a non-vacuum thermal insulation structure. Whenthe auxiliary thermal insulation structure is provided for the cableunit, the core-housing pipe which comprises the cable unit may bestructured as a thermal insulation layer itself, or a thermal insulationlayer may be formed outside the housing which comprises the cable unit.Various kinds of known materials can be used as a thermal insulationmaterial for the auxiliary thermal insulation structure, provided thatnecessary thermal insulation characteristics be satisfied.

<Duct>

It is preferable that at least either one of a cable unit and a coolanttransport channel be housed in a duct the outside of which is coveredwith a thermal insulation member. Housing the cable unit in the ductmakes it possible to manufacture “the cable unit or the coolanttransport tube” and “an assembly of the duct, a thermal insulationmember and a sealing member” separately. Thus, in a subsequentmanufacturing process, a superconducting cable can be structured byinserting the cable unit or the coolant transport tube into the duct,and thereby the efficiency in the manufacture and construction of thecable can be increased. Particularly, by inserting a cable unit or acoolant transport tube into the corresponding duct respectively, thecable unit and the coolant transport tube can be installedindependently. In such case, since a duct is provided for each cableunit or coolant transport tube, it is possible to easily replace a thinghoused in the duct.

It is desirable to make the duct to have airtight structure. Forexample, at both ends of the duct which houses a cable unit, at least agap between the duct and either the cable unit or the coolant transporttube should be airtightly sealed. In such case, it is desirable for thepipe housing the cable unit to have a vacuum thermal insulationstructure. When the inside of the duct is made airtight and the housingpipe of the vacuum sealing structure is used, it is possible to restrainthe decrease in the thermal insulation performance of the housing pipeeven if the vacuum sealing structure of the housing pipe is broken.Particularly, it is preferable to evacuate the inside of the duct aftersealing both ends of the duct. With this structure, since the inside ofthe duct is maintained in a vacuum state, it is possible to moreeffectively restrain the thermal insulation performance of the cableunit from deteriorating even if the vacuum sealing structure of thehousing pipe is broken.

<Installation Mode of the Superconducting Cable>

Any installation mode can be used for laying a superconducting cable ofthe present invention: laying underground or in a concrete, installingin the air, or placing on the ground surface, etc. Particularly, layingunderground or in a concrete enables the superconducting cable toexhibit more efficient thermal insulation performance since the eartharound the superconducting cable has a thermal insulation function.

<The Kind of the Superconducting Cable>

The superconducting cable of the present invention can be used as eitherof a direct current (DC) cable and an alternating current (AC) cable.Particularly, with the DC cable, since there is no alternating currentloss and the loss is only due to penetrating heat, it is possible toconstruct a power cable line in which the loss is minimized by theefficient thermal insulation of the thermal insulation member.

ADVANTAGEOUS EFFECT OF THE INVENTION

The superconducting cable of the present invention provides thefollowing effects.

(1) By arranging a thermal insulation member maintained in a non-vacuumcondition outside a cable unit, a predetermined thermal insulationproperty can be maintained without adopting a vacuum thermal insulationstructure. Thus, it is unnecessary to perform the maintenance andcontrol of the vacuum performance as required in the case of aconventional superconducting cable. Accordingly, the following effectscan be expected, for example: (A) the structure of the superconductingcable can be simplified; (B) a reduction of the cable cost can beachieved; (C) it is possible to avoid such a situation as in the case ofa conventional superconducting cable, in which the power transmissionstops due to the malfunction of the vacuum performance of the thermalinsulation pipe.

(2) By equipping the thermal insulation member with a sealing member, itis made possible to prevent the permeation of moisture into the thermalinsulation member, thereby maintaining the thermal insulation propertyof the thermal insulation member.

(3) Since the thermal insulation member bear the thermal insulationfunction, the cable unit itself is not required basically to have athermal insulation function, and it is possible to decrease the diameterof the cable unit.

(4) It is possible to construct a superconducting cable line havinghigher reliability since the thermal insulation member can maintain thethermal insulation property of a cable unit even if a malfunction occursto the vacuum performance when a vacuum thermal insulation structure isadopted for the housing pipe of the cable unit.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, preferred embodiments of the invention will be described.

Example 1

First, a superconducting cable of the present invention will bedescribed, using a case of underground installation as an example. FIG.1 is a schematic drawing showing the underground installation conditionsof a superconducting cable of the present invention in Example 1.

This superconducting cable has, as shown in FIG. 1, a cable unit 100, athermal insulation member 200 covering the cable unit 100, and a sealingmember 300 covering the thermal insulation member 200, and is laidunderground inside the earth G.

The single core superconducting cable member 100 has a former 111, asuperconductor layer 112, an electrical insulation layer 113, ashielding layer 114, a protective layer 115, a core-housing pipe 120 inthe enumerated order from the center as shown in FIG. 2. Of thesecomposition members, the items including the former 111 through theprotective layer 115 constitute a core 110, and the core 110 is housedin the core-housing pipe 120. A superconducting wire is used in theconductor layer 112 and the shielding layer 114. The superconductingwire used in the cable unit 100 is maintained in a superconducting stateby circulating a coolant (in this case: liquid-nitrogen) in the spacebetween the core 110 and the core-housing pipe 120.

The former 111 was made stranding a plurality of insulated copper wires.By adopting the stranded-wire structure for the former 111, both thereduction of alternating current loss and the restraining of temperaturerise due to an excess current can be achieved at the same time. In thisexample, the unevenness caused by a trench due to stranding andappearing at the outer circumferential surface of the former 111 isdecreased to the practically possible minimum extent by designing thestrands arranged on the outer peripheral side to be thinner than thestrands on the central side.

The superconductor layer 112 was formed using Bi-2223-based Ag—Mnsheathed tape wires having a thickness of 0.24 mm and a width of 3.8 mm.The tape wires were wound around the former in multiple layers so as toform the superconductor layer 112. In the conductor layer 112, thewinding pitches of the superconducting wires differ from layer to layer.In addition, the winding direction is changed by each layer or aplurality of layers, and thereby it is made possible to cause theelectric current to flow uniformly through each layer.

The electrical insulation layer 113 is formed on the outer periphery ofthe superconductor layer 112. This electrical insulation layer 113 canbe formed using, for example, an insulation tape made by laminatingkraft paper and a plastic film such as polypropylene (PPLP: registeredtrademark, from Sumitomo Electric Industries, Ltd.).

The shielding layer 114 is provided on the electrical insulation layer113. The shielding layer 114 is formed by winding the same kind ofsuperconducting wire as that used for the conductor layer 112. Byleading an electric current to this shielding layer 114 in the oppositedirection substantially at the same size as the conductor layer 112,thereby offsetting the magnetic field which occurs from the conductorlayer 112, it is possible to prevent the magnetic field from leakingoutside.

Moreover, the protective layer 115 is formed by winding kraft paper onthe shielding layer 114. This protective layer 115 mainly protects theshielding layer 114 mechanically and electrically insulates it from thecore-housing pipe 120.

The core 110 which comprises the above-mentioned components, i.e., itemsincluding the formers 111 to the protective layer 115, is accommodatedin the core-housing pipe 120. In this case, a corrugated pipe made ofstainless steel is used for the core-housing pipe 120. A coolant forcooling a superconducting wire is circulated in the core-housing pipe120. The core-housing pipe 120 is neither of double-pipe structure norequipped with a thermal insulation structure for maintaining the coolantat cryogenic temperature.

The thermal insulation member 200 is arranged in such a manner as tocover the circumference of the above-mentioned core-housing pipe 120(FIG. 1). Here, glass wool was used as the thermal insulation member200. This thermal insulation member 200 is provided in a thickness whichis capable of the thermal insulation property necessary for allowing thecoolant in the cable unit to maintain cryogenic temperature. In thisexample, the thermal insulation member 200 is arranged in a manner suchthat the sectional shape is substantially rectangular. This sectionalshape, which may be determined according to the conditions of theinstallation site and the like, is not limited to the rectangular form,and it may be circular or other form.

Moreover, the outer periphery of the thermal insulation member 200 iscovered with the sealing member 300. The sealing member 300 preventsmoisture from permeating into the thermal insulation member. In thisexample, the sealing member was made by winding a stainless sheet aroundthe outer periphery of the thermal insulation member 200 and joining theedge of the sheet by welding.

In the superconducting cable having such composition, it is unnecessaryto perform the maintenance and control of the vacuum because no vacuumthermal insulation layer is used. Also, in a conventionalsuperconducting cable, there may occasionally be a situation where powertransmission stops if a malfunction occurs to the thermal insulationproperty of the vacuum thermal insulation layer. However, in the cableof the present invention, such situation can be avoided. Moreover, byusing a sealing member, the thermal insulation performance of thethermal insulation member can be maintained for a long period.

As a modification of this example, a silica aerojel may be used insteadof the above-mentioned thermal insulation member 200. As for the silicaaerojel, Pyrogel (trade name) of Aspen Aerogels Inc., of the U.S.A., orthe like may be used. With the silica aerojel, it is possible to makethe thickness of the thermal insulation member 200 thinner as comparedwith the other materials since the silica aerojel has not only a lightweight but also an excellent thermal insulation property.

Example 2

In the following described is a superconducting cable of the presentinvention in which a plurality of cable units are used. FIG. 3 is aschematic drawing showing underground installation conditions of asuperconducting cable of the present invention in Example 2. In thisexample, mainly points of differences as compared with Example 1 will bedescribed, omitting an explanation about the common compositions.

In this example, three cable units 100, which are the same kind as thatused in Example 1, are used, and they are arranged in a state ofcontacting with each other in triangular positions inside a thermalinsulation member 200. The thermal insulation member 200 is formed bywinding a super insulation around the group of the cable units.

Thus, arranging three cable units 100 at mutually close positions in thethermal insulation member makes it possible to decrease the amount ofpenetrating heat per cable unit, in addition to the effects which can beobtained in Example 1. This is because the total area of contact betweenthe cable unit group and the thermal insulation member 200 is decreasedin the case where the three cable units 100 are arranged in a mutuallycontacting condition, as compared with the case in which each cable unit100 is arranged separately in the thermal insulation member 200 andbecause the cable units can mutually cool.

Example 3

Next, a superconducting cable of the present invention is describedusing an exemplary case in which a coolant transport tube is combinedwith Example 2. FIG. 4 is a schematic drawing showing undergroundinstallation conditions of a superconducting cable of the presentinvention in Example 3. In this example, mainly points of differences ascompared with Example 2 will be described, omitting an explanation aboutthe common compositions.

In this example, three coolant transport tubes 400 are arranged eachadjacent to the respective three cable units 100, and the cable units100 and the coolant transport tubes 400 are arranged altogether atpositions forming a reversed triangular shape as a whole in the thermalinsulation member 200. The coolant transported in the coolant transporttube 400 was liquid hydrogen (coolant temperature: about 20 K).

The amount of penetrating heat per cable unit can be reduced also in thecase of this example as in Example 2. In addition, it is possible tocause the coolant transport tube 400 to cool the cable unit 100 becausethe coolant transport tube 400 is colder than the cable unit 100.

A modification of this example is, for example, to equip the cable unit100 with an auxiliary thermal insulation structure. When the coolant ofthe cable unit 100 is liquid-nitrogen (boiling point: about 77 K,melting point: about 63 K) and the coolant of the coolant transport tube400 is liquid-hydrogen (boiling point: about 20 K), the liquid-nitrogenof cable unit 100 might so excessively be cooled as to be solidified, orthe liquid-hydrogen of the coolant transport tube 400 might be so warmedas to vaporize, if the cable unit 100 and the coolant transport tube 400are disposed too close to each other. If an auxiliary thermal insulationstructure is provided for the cable unit 100, it is possible to restrainthe liquid-nitrogen of cable unit 100 from being cooled more thannecessary or to restrain the liquid-hydrogen of the coolant transporttube 400 from being warmed up. The auxiliary thermal insulationstructure may be formed, for example, by providing a plastic outercovering outside the corrugated stainless steel pipe which is acore-housing pipe.

Example 4

In the following described is a modification of the superconductingcable of the present invention, in which the composition of the thermalinsulation member in Example 1 is changed. FIG. 5 is a schematic drawingshowing underground installation conditions of the superconducting cableof the present invention in Example 4. In this example also, mainlypoints of differences as compared with Example 1 will be described,omitting an explanation about the common compositions.

In this example, a thermal insulation member was comprised of two kindsof materials. That is, a multi-layer thermal insulation 210 is providedon the inner circumferential side near the cable unit, and a fillingthermal insulation 220 is provided on the outer peripheral side apartfrom the cable unit. More specifically, a super insulation is used asthe multi-layer thermal insulation 210, and an expandable plastic isused as the filling thermal insulation 220.

By combining the multi-layer thermal insulation 210 and the fillingthermal insulation 220, it is made possible to effectively block offboth the heat radiation and the heat transmission and to obtain a highthermal insulation property.

Example 5

Next described is a modification of the superconducting cable of thepresent invention, in which the cable unit of Example 2 is accommodatedin a duct. FIG. 6 is a schematic drawing showing undergroundinstallation conditions of the superconducting cable of the presentinvention in Example 5. In this example also, mainly points ofdifferences as compared with Example 2 will be described, omitting anexplanation about the common compositions.

In this example, each of three cable units 100 is housed in a duct 500.According to this structure, three cable units 100 are preparedbeforehand, and an assembly is separately prepared beforehand, in whicha common thermal insulation member 200 is arranged outside three ducts500 and the outer periphery of the thermal insulation member 200 iscovered with a sealing member 300. Thus, a superconducting cable can beobtained by putting each of the cable units 100 into the respective duct500 in the assembly. Therefore, the installation of the superconductingcable can be made on the unit-by-unit basis.

In an exemplary modification of this example, the core-housing pipe forthe cable unit 100 is a vacuum thermal insulation pipe having a doublepipe structure, and in addition, the inside of the duct 500 is alsoevacuated after the ends of the duct 500 have been sealed. According tothis structure, the thermal insulation property of the cable unit 100will not decrease, since the vacuum state of the duct 500 is maintainedeven if the vacuum sealing of the core-housing pipe is broken. In thiscase, both the vacuum level of the core-housing pipe and that of theduct may be lower than the vacuum level of the thermal insulation pipeof a conventional superconducting cable. The reason for this is becausethe thermal insulation property of the cable unit 100 is maintained bythe thermal insulation member 200 covering the outside of the cable unit100.

Example 6

Next described is a modification of the superconducting cable of thepresent invention, in which the structure of the cable unit in Example 1is changed. FIG. 7 is a cross-sectional view of the cable unitcomprising a single core-type superconducting cable in Example 6. Inthis example also, mainly points of differences as compared with Example1 will be described, omitting an explanation about the commoncompositions.

In this example, the core-housing pipe 120 for the cable unit 100 ofExample 1 is designed to be a vacuum thermal insulation structureconsisting of double pipes. That is, the core-housing pipe 120 has aninner pipe 121 and an outer pipe 122, and a super insulation is arrangedbetween the pipes 121 and 122, and the space therebetween is evacuated.

According to the structure of this example, the maintenance and controlof the vacuum cannot be made unnecessary because a vacuum thermalinsulation structure is used in the core-housing pipe 120; however, evenif the malfunction occurs with respect to the vacuum performance of thecore-housing pipe 120, the thermal insulation performance of the cableunit 100 is maintained by means of the thermal insulation member, andaccordingly a superconducting cable line having higher reliability canbe built. In this example, an explanation is made about a singlecore-type superconducting cable; however, in the case of athree-core-in-one type superconducting cable, the cable units may havethe same structure as in FIG. 8.

INDUSTRIAL APPLICABILITY

The superconducting cable of the present invention can be used suitablyas an electric power transportation means.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic drawing showing the underground installationconditions of a superconducting cable of the present invention inExample 1.

FIG. 2 is a cross-sectional view of the cable unit comprising asuperconducting cable of Example 1.

FIG. 3 is a schematic drawing showing the underground installationconditions of a superconducting cable of the present invention inExample 2.

FIG. 4 is a schematic drawing showing the underground installationconditions of a superconducting cable of the present invention inExample 3.

FIG. 5 is a schematic drawing showing the underground installationconditions of a superconducting cable of the present invention inExample 4.

FIG. 6 is a schematic drawing showing the underground installationconditions of a superconducting cable of the present invention inExample 5.

FIG. 7 is a cross-sectional view of the cable unit comprising a singlecore-type superconducting cable in Example 6.

FIG. 8 is a sectional view of a conventional superconducting cable.

DESCRIPTION OF THE REFERENCED NUMERALS

-   -   100 cable unit, 110 core, 120 core-housing pipe,    -   111 former, 112 superconductor layer,    -   113 electrical insulation layer, 114 shielding layer,    -   115 protective layer, 121 inner pipe, 122 outer pipe,    -   200 thermal insulation member,    -   210 multi-layer thermal insulation,    -   220 filling thermal insulation, 300 sealing member,    -   400 coolant transport tube, 500 duct,    -   600 thermal insulation pipe,    -   610 inner pipe, 620 outer pipe,    -   630 anticorrosion layer, G earth

1. A superconducting cable comprising a cable unit, a thermal insulationmember, and a sealing member, the cable unit being composed of acore-housing pipe accommodating a core having a superconductor layer andan electrical insulation layer, the thermal insulation member beingprovided outside the cable unit and maintained in a non-vacuum state,the sealing member preventing the permeation of moisture into thethermal insulation member.
 2. A superconducting cable as set forth inclaim 1, wherein the core-housing pipe is not equipped with a thermalinsulation layer.
 3. A superconducting cable as set forth in claim 1,wherein the thermal insulation member is composed of at least either oneof a multi-layer thermal insulation and a filling thermal insulation. 4.A superconducting cable as set forth in claim 3, wherein the innercircumferential part of the thermal insulation member is a multi-layerthermal insulation and the outer peripheral part of the thermalinsulation member is a filling thermal insulation.
 5. A superconductingcable as set forth in any of claims 1, wherein a plurality of cableunits are arranged at positions close to each other.
 6. Asuperconducting cable as set forth in claim 5, wherein an intervalexisting between the respective cable units is equal to or less than theouter diameter of the cable unit.
 7. A superconducting cable as setforth in any of claims 1, wherein a coolant transport tube is providednear a cable unit, and wherein the cable unit and the coolant transporttube are covered with a common thermal insulation member.
 8. Asuperconducting cable as set forth in claim 7, wherein the intervalexisting between a cable unit and a coolant transport tube is equal toor less than the outer diameter of the cable unit.
 9. A superconductingcable as set forth in claim 7, wherein an auxiliary thermal insulationstructure is provided at least at either one of the cable unit and thecoolant transport tube.
 10. A superconducting cable as set forth inclaim 7, wherein at least either one of a cable unit and a coolanttransport tube is housed in a duct, a thermal insulation member beingarranged on the outer side of the duct.
 11. A superconducting cable asset forth in claim 10, wherein a gap between the duct and at leasteither one of the cable unit and the coolant transport tube isairtightly sealed.
 12. A superconducting cable as set forth in claim 11,wherein the inside of the duct is evacuated.
 13. A superconducting cableas set forth in any of claims 1, wherein the thermal insulation memberis made of aerojel.